1 Introduction

The following text originally came from the Ghosh UZH UFO application

As the global climate is experiencing more heat, and less rainfall - it is reasonable to expect that the distributions of these variables (temperature and rainfall) are becoming more skewed and asymmetric towards the extreme values (see figure 1.1 below, which comes from the UZH UFO proposal, where it was figure 2). With the availability of more open access long-term databases, it is possible to address how different taxa respond at the community level.

Introduction figure

Figure 1.1: Introduction figure

As a preliminary work, I have already gathered long-term (median of 41 years) species-level abundance data for 2043 terrestrial and 716 aquatic communities. My recent result (manuscript in preparation) shows that the community stability is different for terrestrial and freshwater taxa and could be better explained considering the different strengths between pairwise species associations at the extremes, called community-level tail association, than with classic correlates of community stability studies (richness and variance ratio).

I will gather global data for annual temperature and rainfall from open access CHELSA database19 and ask how variability in temperature and precipitation would affect terrestrial taxa (birds, mammals, invertebrates, plants). For freshwater taxa (fish, phytoplankton, invertebrates), mostly temperature variability would be considered. In marine realm, sampling is spatially not consistent over the years20 and also very few long-term (>20yrs) data sampled compared to terrestrial and freshwater, thus I will focus only on the latter two realms. Also, species-level biomass (or body size) data will be gathered considering different generation times across taxa.

I will focus on community stability and will build a Bayesian model incorporating climatic factors (e.g., variability, skewness, range of maximum and minimum of temperature-distribution over the years etc.). While scientists studied thermophilization in the context of warming-related turnover in communities, no predictive model for community stability has been developed, to date, assessing the effect of extreme climatic events across taxa using a global database. This study will inform the current status of communities across multiple taxa facing climatic extremes and help prioritize conservation efforts (see Work Package 2).

I will gather annual climate data (mean, minimum, maximum for temperature, rainfall) and compute the variability, and the skewness of their distribution for the study period over which the community dynamics was studied. I will compute the richness (number of total species and dominant species that were present minimum 70% of the total years sampled), variance ratio, community level total tail association from pairwise synchrony as drivers. These drivers appeared as significant for explaining variation in community stability from my recent study (manuscript in preparation). I will compute the response variable community stability as the inverse of community-variability over the study period. Then, I will build a Bayesian model to see the effect of climate parameters, on the stability-driver relationships for different taxa.

2 Data

2.1 Data structure

Total 1948 community timeseries we have collected for the timespan 1979-2019. 4 taxa are considered - birds, fish, freshwater invertebrates, terrestrial invertebrates. Below is the summary of the datatable. Description of each column is given in README.txt

## 'data.frame':    1948 obs. of  43 variables:
##  $ source         : chr  "BioTIME" "BioTIME" "BioTIME" "BioTIME" ...
##  $ STUDY_ID       : chr  "57" "229" "229" "229" ...
##  $ newsite        : chr  "57" "STUDY_ID_229_LAT35.04016_LON-83.36127" "STUDY_ID_229_LAT35.11187_LON-83.39091" "STUDY_ID_229_LAT35.14137_LON-83.29577" ...
##  $ REALM          : chr  "Freshwater" "Freshwater" "Freshwater" "Freshwater" ...
##  $ TAXA           : chr  "fish" "fish" "fish" "fish" ...
##  $ ORGANISMS      : chr  "fish" "fish" "fish" "fish" ...
##  $ initR          : int  76 24 24 24 24 24 24 30 30 31 ...
##  $ nsp            : int  34 14 14 14 14 14 14 11 11 10 ...
##  $ nyr_used       : int  32 23 23 23 23 23 23 20 20 28 ...
##  $ startyr        : int  1981 1990 1990 1990 1990 1990 1990 1995 1995 1979 ...
##  $ endyr          : int  2012 2013 2013 2013 2013 2013 2013 2014 2014 2006 ...
##  $ nint           : int  561 91 91 91 91 91 91 55 55 45 ...
##  $ nind           : int  503 59 59 59 59 59 59 46 46 36 ...
##  $ npos           : int  35 29 29 29 29 29 29 7 7 7 ...
##  $ nL             : int  24 21 21 21 21 21 21 3 3 7 ...
##  $ nU             : int  11 8 8 8 8 8 8 4 4 0 ...
##  $ nneg           : int  23 3 3 3 3 3 3 2 2 2 ...
##  $ L              : num  3.03 2.56 2.56 2.56 2.56 ...
##  $ U              : num  -1.252 -0.633 -0.633 -0.633 -0.633 ...
##  $ f_nind         : num  0.897 0.648 0.648 0.648 0.648 ...
##  $ f_nL           : num  0.0428 0.2308 0.2308 0.2308 0.2308 ...
##  $ f_nU           : num  0.0196 0.0879 0.0879 0.0879 0.0879 ...
##  $ f_nneg         : num  0.041 0.033 0.033 0.033 0.033 ...
##  $ cvsq_real      : num  1.565 0.189 0.189 0.189 0.189 ...
##  $ cvsq_indep     : num  1.5001 0.0963 0.0963 0.0963 0.0963 ...
##  $ phi            : num  1.04 1.96 1.96 1.96 1.96 ...
##  $ phi_LdM        : num  0.454 0.552 0.552 0.552 0.552 ...
##  $ skw_real       : num  5.172 0.363 0.363 0.363 0.363 ...
##  $ skw_indep      : num  5.064 0.612 0.612 0.612 0.612 ...
##  $ phi_skw        : num  1.021 0.593 0.593 0.593 0.593 ...
##  $ iCV            : num  0.799 2.303 2.303 2.303 2.303 ...
##  $ iCValt         : num  1.81 1.9 1.9 1.9 1.9 ...
##  $ LONGITUDE      : num  -89.5 -83.4 -83.4 -83.3 -83.5 ...
##  $ LATITUDE       : num  44 35 35.1 35.1 35.2 ...
##  $ t_med          : num  2809 2865 2867 2863 2863 ...
##  $ tmax_med       : num  2860 2917 2919 2915 2915 ...
##  $ tmin_med       : num  2766 2819 2822 2818 2818 ...
##  $ t_skw          : num  0.4702 0.1315 0.0838 0.0941 0.143 ...
##  $ tmax_skw       : num  0.658 0.262 0.247 0.239 0.258 ...
##  $ tmin_skw       : num  0.313 0.292 0.324 0.315 0.366 ...
##  $ t_var          : num  249 438 417 422 438 ...
##  $ trend_t_tau    : num  0.363 0.363 0.363 0.363 0.363 ...
##  $ trend_t_tau_sig: int  1 1 1 1 1 1 1 1 1 1 ...

But see the below table which shows the sample size for each taxa and the datasource, we have very few sample size for terrestrial invertebrates. I feel it’s better to write a paper about north american birds vs european fish (atleast we have >500 datapoints for birds and fish). But I am open to other ideas. I don’t know which kind of data requirement we need for response diversity, but if we can have the body size or biomass (as trait) data then I can test the H0: whether response diversity increases the stability or influenced by temperature?

## # A tibble: 12 × 3
##    TAXA                      source              n
##    <chr>                     <chr>           <int>
##  1 birds                     BBS              1227
##  2 birds                     BioTIME            19
##  3 fish                      BioTIME            11
##  4 fish                      BioTIMEx           25
##  5 fish                      RivFishTIME       544
##  6 freshwater invertebrates  BioTIME            15
##  7 freshwater invertebrates  BioTIMEx            2
##  8 freshwater invertebrates  InsectRoel         79
##  9 freshwater invertebrates  SwissLakeZoo        5
## 10 freshwater invertebrates  Zooplankton2014     7
## 11 terrestrial invertebrates BioTIME            11
## 12 terrestrial invertebrates BioTIMEx            3

2.2 Sitemap for each taxa

3 Methods

I want to see how community stability-drivers relationship would affect by the changing environmental variable (annual temperature distribution). Temperature could vary in many ways (see 3.1). I am considering three aspects of environmental (temperature) timeseries here: median of annual temperatures (\(t_{med}\)) during the study periods, trend (\(t_{trend}\)) and skewness (\(t_{skw}\)) of annual temperature timeseries for a given community. My intuition is:

  • community stability would be affected by any of these temperature component either directly or indirectly via the drivers.
  • As \(t_{med}\), \(t_{trend}\) changes, diversity-stability relationship should be affected, so stability would change via portfolio effect. e.g. terrestrial plants, beetles, and vertebrates show declining richness with incresing temperature in the past studies.
  • Similarly, changing \(t_{med}\), \(t_{trend}\) should relate how species interactions get modified in a changing environment. For example, as temperature increases (or decreases) \(t_{med}\), community might loose some species, and might be dominated by fewer species which may or may not be synchronous, depending on the species-traits at that particular environment. But if \(t_{trend}\) increases, the community is exposing to warmer environment with years, then maybe warm adapted species will become dominant and species with similar traits can have higher synchrony. I am not sure, what will happen - but we can see how community-level response (avg of all species’response to warming in that community) changes with temperature?
  • Changing \(t_{skw}\), means frequent extreme events (like heatwaves, negative skewed annual temperature distribution), and it should be related to tail-dependent synchrony, where pairwise synchrony between species gets stronger beyond a certain threshold.
Temperature timeseries figure

Figure 3.1: Temperature timeseries figure

Temperature timeseries figure with real data

Figure 3.2: Temperature timeseries figure with real data

3.1 Variables estimated and modelled

(Perhaps make this into a table.)

Let \(N_{i,t,s}\) be the abundance (sometimes it was biomass data only if abundance data were not available) of species \(i\) at time \(t\) at site \(s\). Total abundance at time \(t\) at site \(s\) is \(N_{t,s} = \sum_{i=1}^{s} N_{t,s,i}\).

Community stability at site \(s\) was estimated as the inverse of the coefficient of temporal variation in total community biomass ?or? abundance: \(TempStab_s = 1 / CV(N_{t,s}) = median(N_{t,s}) / IQR(N_{t,s})\)

Species richness at site \(s\) was estimated as the number of total species and dominant species that were present minimum 70% of the total years sampled.

Comunity variance ratio: a measure of synchrony.

Community level total tail association from pairwise synchrony:

Temperature median:

Temperature trend:

Temperature variability:

Temperature skew:

4 Results

4.1 Community stability exploration

Stability-diversity relationship for birds and fish.

Figure 4.1: Stability-diversity relationship for birds and fish.

4.1.1 Birds

Stability-diversity relationship for birds at different temperature levels

Figure 4.2: Stability-diversity relationship for birds at different temperature levels

Stability-temperature relationship for bird communities at different richness levels

Figure 4.3: Stability-temperature relationship for bird communities at different richness levels

Stability-synchrony relationship for birds at different temperature levels

Figure 4.4: Stability-synchrony relationship for birds at different temperature levels

Synchrony-temperature relationship (scatterplot)

Figure 4.5: Synchrony-temperature relationship (scatterplot)

Synchrony-temperature relationship (boxplot)

Figure 4.6: Synchrony-temperature relationship (boxplot)

Synchrony richness relationship.

Figure 4.7: Synchrony richness relationship.

Synchrony temperature relationship.

Figure 4.8: Synchrony temperature relationship.

Stability - temperature skew relationship.

Figure 4.9: Stability - temperature skew relationship.

4.1.1.1 Basic statistics for birds

Model of bird stability:

term estimate std.error statistic p.value
(Intercept) 26.9118 8.9852 2.9951 0.0028
log2(nsp) -4.2183 1.7294 -2.4391 0.0149
t_med -0.0096 0.0032 -3.0393 0.0024
log2(nsp):t_med 0.0016 0.0006 2.7063 0.0069

Model of bird synchrony:

term estimate std.error statistic p.value
(Intercept) -12.5849 10.5522 -1.1926 0.2332
log2(nsp) 1.6317 2.0310 0.8034 0.4219
t_med 0.0046 0.0037 1.2447 0.2135
log2(nsp):t_med -0.0008 0.0007 -1.1058 0.2690

4.1.1.2 Bird conclusions

Bird communities display a positive richness stability relationship. This relationship is stronger at higher temperatures. Equally, high richness bird communities are more stable at higher temperatures, while low richness bird communities are less stable at higher temperatures.

There is some suggestion that this may be explained by synchrony, but the statistics show no strong associations of synchrony with \(t_med\) or synchrony.

4.1.2 Fish

Stability-diversity relationship at different temperature levels

Figure 4.10: Stability-diversity relationship at different temperature levels

Stability-temperature relationship at different richness levels

Figure 4.11: Stability-temperature relationship at different richness levels

Stability-synchrony relationship at different temperature levels

Figure 4.12: Stability-synchrony relationship at different temperature levels

Synchrony-temperature relationship (scatterplot)

Figure 4.13: Synchrony-temperature relationship (scatterplot)

Synchrony-temperature relationship (boxplot)

Figure 4.14: Synchrony-temperature relationship (boxplot)

Synchrony richness relationship.

Figure 4.15: Synchrony richness relationship.

Synchrony temperature relationship.

Figure 4.16: Synchrony temperature relationship.

Stability - temperature skew relationship.

Figure 4.17: Stability - temperature skew relationship.

4.1.2.1 Fish basic statistics

Model of fish stability:

term estimate std.error statistic p.value
(Intercept) -18.8945 5.1784 -3.6488 0.0003
log2(nsp) 6.8215 2.4501 2.7842 0.0055
t_med 0.0068 0.0018 3.6872 0.0002
log2(nsp):t_med -0.0024 0.0009 -2.7995 0.0053

Model of fish synchrony:

term estimate std.error statistic p.value
(Intercept) 9.6614 4.1029 2.3548 0.0189
log2(nsp) -3.3940 1.9413 -1.7483 0.0809
t_med -0.0036 0.0015 -2.4585 0.0142
log2(nsp):t_med 0.0011 0.0007 1.6228 0.1052

4.1.2.2 Fish conclusions

Fish communities display a positive richness stability relationship at low temperature, and a negative one at higher temperatures. This is the opposite of the interaction pattern for birds, where the relationship became more positive when temperature was higher. Equally, high richness bird communities are slightly less stable at higher temperatures, while low richness bird communities are more stable at higher temperatures (again the opposite to the bird patterns).

Not sure, at present, how much can be explained by synchrony, but the statistics show no strong associations of synchrony with t_med or richness.

4.2 Explanations

So, from the exploratory plots we can see: at higher temperature positive stability-diversity relationship becomes stronger for birds but for fish it becomes weaker. Also fish becomes more asynchronous with increasing temperature. So, why does that happen? to find this we could explore how much the bird species and fish species are consistent to temperature change across all communities.

Which pattern / finding are we trying to explain with the following two graphs?

Distribution of temperature skewness, birds and fish together.

Figure 4.18: Distribution of temperature skewness, birds and fish together.

Distribution of temperature skewness, birds and fish separate. Fish communities generally experience more negatively skewed temperature fluctuations. In the fish SEM we see that t_skw directly affects stability, with more negative skew being associated with higher stability. No evidence of association of t_skw and stability in birds.

Figure 4.19: Distribution of temperature skewness, birds and fish separate. Fish communities generally experience more negatively skewed temperature fluctuations. In the fish SEM we see that t_skw directly affects stability, with more negative skew being associated with higher stability. No evidence of association of t_skw and stability in birds.

The cue is: if fish species are not much consistent in their response to warming and vary across sites, that means you cannot make a conclusion that they would become similar with changing temperature. On another note, bird species should be more consistent towards warming if their is no change in their synchrony level across communities. Another possibility could be with changing temperature you might loose some species (its not just number of individuals, it will selectively prefer few species with better fitness), and then the communities will be dominated by few species with similar traits (so increasing synchrony). we will test this below.

From the above plots, we can see birds are showing consistent response-distribution across all temperature change, i.e., in either end of temperature spectrum (low or high end). That’s why the synchrony level remains similar for birds. But for fish, warming increases the richness (addition of new species), and as fish species now become more variable in response to temperature sensitivity (trait-variation), they show more asynchrony compared to low temperature scenario where only few species exists (see smaller circle size on the map for lowT,<50%CI) and show similar traits (so more synchrony). Note: when I show this to Frank, he commented on how much robust is the pattern for fish at low T as there are only few species existed across 145 sites - so it also depends on how we considered the lowT-highT communities. I set beyond 50% CI of temperature range as low/high. Even if I decrease that to 30% CI, still very few species found in low T sites (15 sp across 203 sites: 80% >0, 20% <0 line).

To further explore this idea: we collected traits data for birds and fish species used in the analysis. For fish-traits, I will use body length measurements, for bird-traits I will use HWI (Hand-wing index). From below figures: at high T, birds have slightly less dispersal ability (lower HWI), but richness is more or less uniformly spread at either temperature range. For fish, at lowT, few large species exists with similar traits (remember the previous histogram plot 90-10) showing higher synchrony, as temperature increases addition of new small fishes in the community (maybe better environment for them to exist in that temperature rather than too cold water) makes them asynchronous with more trait variation (histogram plot 66-34).

When I showed this to Blake, he was not convinced by the idea to split the data into two: low/high based on t_med (to him this temperature difference is more on latitudinal differences as shown in the map), and same species can exist in both communities - so why changing t_med should change the synchrony level for fish? and getting different bodysize fish from low/high t_med (fewer big fish in lowT and many smaller fish in highT) is not explaining why big fish should be more synchronous - is it because of fewer species (richness) or because bigger fish abundance change needs more time - not on annual scale?

So, I thought to make a plot of how community-level average response traits (average of standardised correlation between species abundance with t_med timeseries across sites) changes with increasing temperature (t_med)? For fish, it should decrease with increasing t_med, whereas for birds it should be a flat relationship.

Possible explanation:

Response variation with temperature

Figure 4.20: Response variation with temperature

Now, we will do a path analysis for a simplistic mixed effect model to see the environmental effects on community stability for both taxa.

So, from the path analysis, what do we see for birds -

  • for birds: increasing temperature trend (communities exposed to continuous warming) decreases species richness, increasing synchrony. (because of similar species traits in warmer condition?)
  • increasing extreme heatwaves (note this is negative skewness) will increase tail dep synchrony, which in turn decreases stability. Here direct effect of t_skw is not significant on stability, as all bird data have equal proportion of +ve and -ve skewness (see above plot). But still tail dependent synchrony is important mechanism for stability, especially for terrestrial taxa (we found this from BioDyn project), and driven by the skewness of temperature time series (extreme events).
  • positive diversity-stability relationship and negative synchrony-stability relationship are observed as expected.

and for fish -

  • overall synchrony (variance ratio) is the important determinant for stability (this we knew from BioDyn project findings), as it connects the environmental effects to stability.
  • both warming scenario (median temperature or temperature trend) increases richness, increasing temperature increases more asynchrony (-ve effect on VR), which is also consistent with more variable traits for the fish species.
  • increasing extremes makes community biomass more variable (-ve effect of heatwaves on stability via t_skw direct effect, not indirect effect through tail-dep synchrony as it is not important driver for freshwater as we found from BioDyn).

5 Discussion